大肠杆菌对营养向上转变的生长反应：生长缓慢的细胞中立即出现的分裂刺激

Growth response of Escherichia coli to nutritional shift-up: immediate division stimulation in slow-growing cells.

作者信息

Sloan J B, Urban J E

出版信息

J Bacteriol. 1976 Oct;128(1):302-8. doi: 10.1128/jb.128.1.302-308.1976.

DOI:10.1128/jb.128.1.302-308.1976

PMID:789337

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC232856/

Abstract

When Escherichia coli 15T- cells growing exponentially at 70- to 80-min doubling times are subjected to a nutritional shift-up via glucose addition, cell division continues at the preshift rate for about 70 min (rate maintenance). The same cells growing at doubling times of 120 min or longer, however, begin to divide at a new faster rate immediately upon glucose addition. In both the rate maintenance and immediate division situations, cell mass, as measured by optical density (OD), begins to increase immediately upon shift-up. Consequently, the OD/cell pattern differs in the two growth-rate transitions. During rate maintenance, the OD/cell ratio increases dramatically for 60 to 70 min, and then slows appreciably and approaches the OD/cell characteristic of the new medium. During immediate division situations, the OD/cell increases only slightly for the first 180 +/- min; then the rate of increase accelerates but does not stop at the OD/cell characteristic of the new medium. Immediate division upon nutritional shift-up apparently depends upon initial doubling times in excess of 115 to 120 min and provision of a readily metabolized carbon source supporting doubling times of about 40 min. Similar immediate division occurs in E. coli B/r and K-12.

摘要

当倍增时间为70至80分钟且呈指数生长的大肠杆菌15T-细胞通过添加葡萄糖进行营养上调时，细胞分裂会以转变前的速率持续大约70分钟（速率维持）。然而，那些倍增时间为120分钟或更长时间而生长的相同细胞，在添加葡萄糖后会立即开始以更快的新速率进行分裂。在速率维持和立即分裂这两种情况下，通过光密度（OD）测量的细胞质量在营养上调后会立即开始增加。因此，在两种生长速率转变过程中，OD/细胞模式有所不同。在速率维持期间，OD/细胞比率在60至70分钟内急剧增加，然后明显减缓并接近新培养基的OD/细胞特征。在立即分裂的情况下，OD/细胞在前180±分钟内仅略有增加；然后增加速率加快，但不会在新培养基的OD/细胞特征处停止。营养上调后的立即分裂显然取决于超过115至120分钟的初始倍增时间以及提供支持约40分钟倍增时间的易于代谢的碳源。在大肠杆菌B/r和K-12中也会发生类似的立即分裂。

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Growth response of Escherichia coli to nutritional shift-up: immediate division stimulation in slow-growing cells.大肠杆菌对营养向上转变的生长反应：生长缓慢的细胞中立即出现的分裂刺激

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本文引用的文献

THE EFFECT OF AMINO ACID DEPRIVATION ON SUBSEQUENT DEOXYRIBONUCLEIC ACID REPLICATION.氨基酸剥夺对后续脱氧核糖核酸复制的影响。

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